Acoustic emission (AE) can be an effective condition monitoring technique for studying different types of wear in tribosystems. In the present paper, a theoretical model is developed in order to correlate acoustic emissions to adhesive wear. According to the model, the characteristics of AE (energy and VRMS) are under the influence of mechanical properties of the mating surfaces (sliding velocity and contact load, supported by surface asperities). By means of the AE technique, this model can be used as a theoretical basis for further analytical and/or experimental investigations in the field of condition monitoring of tribosystems.
Archard, J.F., 1953, “Contact and Rubbing of Flat Surfaces,” Journal of Applied Physics, Vol. 24, pp. 980–988.
Baranov, V.M., E.M. Kudryavtsev, and G.A. Sarychev, 1997, “Modelling of the Parameters of Acoustic Emission under Sliding Friction of Solids,” Wear, Vol. 202, No. 2, pp. 125–133.
Baranov, Victor, Evgeny Kudryavtsev, Gennady Sarychev, and Vladimir Schavelin (eds.), 2007, “Chapter 2: Simulation of Characteristics of Acoustic Emission in Friction,” Tribology and Interface Engineering Series, Vol. 53, pp. 37–96, Elsevier, New York, NY.
Boness, R.J., and S.L. McBride, 1991, “Adhesive and Abrasive Wear Studies using Acoustic Emission Techniques,” Wear, Vol. 149, No. 1–2, pp. 41–53.
Boness, R.J., S.L. McBride, and M. Sobczyk, 1990, “Wear Studies Using Acoustic Emission Techniques,” Tribology International, Vol. 23, No. 5, pp. 291–295.
Bowden, F.P., and D. Tabor, 1950, The Friction and Lubrication of Solids, Oxford University Press, Oxford, UK.
Ebrahimkhanlou, A., and S. Salamone, 2018, “Single-Sensor Acoustic Emission Source Localization in Plate-Like Structures Using Deep Learning,” Aerospace, Vol. 5, No. 2, doi:10.3390/aerospace5020050.
Ebrahimkhanlou, A., and S. Salamone, 2017a, “A Probabilistic Framework for Single-Sensor Acoustic Emission Source Localization in Thin Metallic Plates,” Smart Materials and Structures, Vol. 26, No. 9, 095026.
Ebrahimkhanlou, A., and S. Salamone, 2017b, “Acoustic Emission Source Localization in Thin Metallic Plates: A Single-Sensor Approach based on Multimodal Edge Reflections,” Ultrasonics, Vol. 78, pp. 134–145.
Fan, Y., F. Gu, and A. Ball, 2010, “Modelling Acoustic Emissions Generated by Sliding Friction,” Wear, Vol. 268, No. 5–6, pp. 811–815.
Hase, A., M. Wada, and H. Mishina, 2008, “The Relationship between Acoustic Emissions and Wear Particles for Repeated Dry Rubbing,” Wear, Vol. 265, No. 5–6, pp. 831–839.
Hase, A., H. Mishina, and M. Wada, 2012, “Correlation between Features of Acoustic Emission Signals and Mechanical Wear Mechanisms,” Wear, Vols. 292–293, pp. 144–150.
Lingard, S., and K.K. Ng, 1989, “An Investigation of Acoustic Emission in Sliding Friction and Wear of Metals,” Wear, Vol. 130, No. 2, pp. 367–379.
Nerz, K.-P., 1988, “Investigations of Tribological Pin-disc Interactions by Digital Acoustic Emission Analysis, Scanning Electron Microscopy and Usual Wear Measurements,” in Non-Destructive Testing, Proceedings of the 4th European Conference, 13–17 September, London, UK, pp. 3042–3055.
Sun, J., R.J.K. Wood, L. Wang, I. Care, and H.E.G. Powrie, 2005, “Wear Monitoring of Bearing Steel Using Electrostatic and Acoustic Emission Techniques,” Wear, Vol. 259, No. 7–12, pp. 1482–1489.
Ukpai, , J.I., R. Barker, X. Hu, and A. Neville, 2013, “Exploring the Erosive Wear of X65 Carbon Steel by Acoustic Emission Method,” Wear, Vol. 301, No. 1–2, pp. 370–382.
79 Page Views
0 PDF Downloads
0 Facebook Shares